Stretchy Electrodes Wire Up Cells

Stretchy Electrodes Wire Up Cells

Cell stretcher: This system, made of a stretchy polymer embedded with four microelectrodes, can be stretched by a micromanipulator (the black clamp) to mimic the electrical and mechanical activity of the heart.

The cells of the heart can be stretched by as much as 100 percent with every beat. But traditional platforms for studying cells are static, limiting researchers’ ability to study these cells in a realistic way in the lab. Now researchers at Purdue University and Stanford University have developed stretchable electrode arrays for studying these cells. These arrays should help develop tissue-engineered grafts to repair the damage caused by heart attacks, and could serve as bio-friendly electrical interfaces in implantable devices. They’re also being used to study how the mechanical stress inflicted during traumatic brain injury changes neurons’ electrical activity over the long term.

The new system, developed by a team led by Babak Ziaie, a professor of electrical and computer engineering at Purdue, consists of a stretchy polymer containing a small array of gold-coated pins. These pins act as microelectrodes that can send and record electrical signals. In the past, the difficulty in designing these electrode arrays has been developing electrical connections for the electrodes that can be stretched without degrading their performance. In the Purdue system, electrical current is carried to and from the electrodes by a liquid metal alloy that flows through channels within the polymer.

The stretchy electrode arrays maintain their electrical properties better than any flexible electrode previously developed. Using a liquid alloy means that resistance to electrical current does not drop when the array is stretched.

This makes them a useful tool for studying and stimulating cardiac cells, says Rebecca Taylor, one of the Stanford researchers working on the project. The heart’s muscle cells receive regular electrical stimulation that causes them to beat. They also experience regular mechanical stresses caused by the beating of the tissue around them. These stimuli tell heart cells to keep acting like heart cells, so mimicking them in the lab is an important first step toward engineering tissue to repair the damage caused by heart attacks or congenital heart defects.

Taylor says that the new electrodes make it possible to stretch and stimulate heart-muscle cells in vitro: “You trick them into thinking they’re in the heart.” These long, beating muscle cells normally lose their shape after about a day in culture, growing still and pulling into small, round shapes. The Stanford researchers’ first goal is to use the stretchy, electrically stimulating cell platform to maintain the cells in their normal state. After that, they plan to use the approach to grow patches of healthy heart tissue for reparative grafts.

Another team of researchers, at Columbia University and Princeton University, are using stretchable electrode arrays to study traumatic brain injury (TBI). This kind of injury results from an acute event like a car accident or a battlefield explosion, but the ill effects grow much worse over the long term as cells in the brain react to the injury by changing their gene-expression patterns, and subsequently their electrical activity. So the hope is that better understanding how mechanical stresses lead to molecular changes in the brain could, in turn, lead to life-saving therapies. “The deformation of brain tissue sets into motion cellular signaling cascades that take some time to develop; very often, that’s what kills you,” says Barclay Morrison, a biomedical engineer at Columbia. Morrison is studying TBI in the lab using stretchable electrodes developed by Sigurd Wagner, a professor of electrical engineering at Princeton.